To genetically engineer cyanobacteria, we chose Synechococcus elongatus PCC 7942 as our engineering host. Our main strategy is to embark on gene double-crossover homologous recombination in S. elongatus PCC 7942 genome, which is the first cyanobacterial strain to be transformed by exogenous DNAs and is reliably transformable through natural uptake of extracellular DNAs.

　　First, we constructed a vector which is able to finish double-crossover homologous gene recombination in S. elongatus PCC 7942. The vector (pPIGBACK) contains 5’- and 3’-ends of the neutral site II (NSII) and an ampicillin resistance gene (AmpR) for antibiotic selection. Then we fused AmpR with double terminator, BBa_B0015, which is proved to be functional in cyanobacteria. Additionally, in order to easily manipulate DNAs for gene cloning and plasmid preparation in E. coli DH5α, the replication origin (ORI) of pBR322 was also introduced to make the plasmid vector replicable in E. coli. Then, in order to overexpress foreign genes in the cyanobacteria, the intrinsic promoter of Rubisco large subunit (PrbcL) was chosen as the target for vector construction. PrbcL regulates the expression of the most abundant proteins in photosynthetic species and has been proven to have a high activity to express foreign genes, so we chose PrbcL as the promoter of our pigment gene.¹

　　The strategy we chose to construct the vector is to fuse B0015 and AmpR together first. Secondly, we fused 5’- and 3’-ends of the neutral site II (NSII) with PBR322 replication origin (ORI) together. At last, we ligated two parts together. The vector (pPIGBACK) is used to transform into PCC7942 with the inserted pigment gene in our experiments. After mass reproduction in E. coli DH5α, PCC7942 were transformed through the uptake of plasmid DNAs extracted from E. coli DH5α. The transformed strains (transformants) were usually successfully obtained after 2 to 3 weeks and survived the ampicillin treatment.

　　Indigoidine is a bacterial natural product with antioxidant and antimicrobial activities. Its bright blue color resembles the industrial dye indigo, thus representing a new natural blue dye that may find uses in industry. In nowadays studies, an Indigoidine synthetase Sc-IndC and an associated helper protein Sc-IndB were identified from Streptomyces chromofuscus ATCC 49982 and successfully expressed in Escherichia coli BAP1 to produce the blue pigment². The IndB gene codes for a putative phosphatase and the IndC gene codes for Indigoidine synthase. Together, these enzymes convert L-glutamine into Indigoidine. Recently, it has been shown that IndC alone can produce Indogoidine, and the inclusion of IndB expression in the system will increase yields significantly³.

　　As we know, L-Glutamine is the direct biosynthetic precursor of Indigoidine, and it is a key amino acid in primary metabolism and thus naturally exists in S. elongatus PCC7942. Because glutamine related products are already existed in S. elongatus PCC7942, we only need to activate the expression of Sc-IndC in S. elongatus PCC7942 which leads to the production of Indigoidine. However, due to the access difficulties of Streptomyces chromofuscus ATCC 49982, we decided to use the previous part for IndC, which has been submitted to the iGEM Parts Registry (BBa_K1152008)⁴. According to the part design, our Indigoidine gene comes from Photorhabdus luminescens laumondii TT01 (DSM15139).

　　Zeaxanthin belongs to carotenoid family and is widely found in the nature. It is also a natural color making corns, carrots and marigolds yellow. Moreover, zeaxanthin is an essential nutrient substance to human’s eyes, and some healthy supplements are made of it. Most of green plants produce zeaxanthin as an intermediate in carotenoid pathway. However, some photosynthetic bacteria such as cyanobacteria lack of zeaxanthin. Therefore, we try to transform zeaxanthin-related genes to cyanobacteria to make them yellow.

　　After paper study, we find nobody has done it before. Under our instructor’s help, we develop a way to make cyanobacteria yellow. We compare the complete carotenoid pathway with Synechococcus elongatus PCC 7942 whole genomic DNA on KEGG and we find every zeaxanthin-related gene is included in PCC 7942 genomic DNA except beta-carotene hydroxylase (crtZ) . And we find crtZ coding sequence with ribosome-binding site is an igem released part (BBa_I742158), which is from a plant pathogen, Pantoea ananatis.

　　We had successfully transformed CrtZ to Escherichia coli to reproduce massively, and then transformed CrtZ with pPIGBACK to Synechococcus elongatus PCC 7942. After a week, the transformed Synechococcus elongatus PCC 7942 expressed more yellow than the control group. To test whether the photosynthetic efficiency is better, we used iodine to measure starch concentration and compare it with wild type.

Black Design

　　Astaxanthin is a high value and natural pink pigment which can be found in microalgae, yeast and some sea creatures. It’s special due to its antioxidant activity and has been suggested to be beneficial in cardiovascular, immune, inflammatory and neurodegenerative diseases and skin health. Although it has lots of benefits, astaxanthin is still a product result in a minority amount in the carotenoid synthesis pathway compare with other carotenoid families and yet, the artificial chemical synthesis cost high and result in the least production.

　　Astaxanthin synthesis does not naturally exist in the S. elongatus PCC7942. But fortunately, after paper research, we found out that S. elongatus PCC7942 has a similar pathway with other microalgae which can synthesize astaxanthin, and the only different is, S. elongatus PCC7942 lack of two necessary gene: beta-carotene ketolase (crtW) and beta-carotene hydroxylase (crtZ) to undergo this pathway. Thus, we use IDT to synthesis these two genes and construct it on pPIGBACK, a vector which can express the carrying genes in S. elongatus PCC7942.